2 * Copyright (C) 1995-2007 University of Karlsruhe. All right reserved.
4 * This file is part of libFirm.
6 * This file may be distributed and/or modified under the terms of the
7 * GNU General Public License version 2 as published by the Free Software
8 * Foundation and appearing in the file LICENSE.GPL included in the
9 * packaging of this file.
11 * Licensees holding valid libFirm Professional Edition licenses may use
12 * this file in accordance with the libFirm Commercial License.
13 * Agreement provided with the Software.
15 * This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
16 * WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR
22 * @brief Implementation of interval analysis
33 #include "interval_analysis.h"
34 #include "execution_frequency.h"
35 #include "firm_common_t.h"
47 /*------------------------------------------------------------------*/
48 /* A new in array via a hashmap. */
49 /* The in array refers to the loop the block is contained in if the */
50 /* block is not in blocks loop. */
51 /*------------------------------------------------------------------*/
61 static set *region_attr_set = NULL;
63 int region_attr_cmp(const void *e1, const void *e2, size_t size) {
64 region_attr *ra1 = (region_attr *)e1;
65 region_attr *ra2 = (region_attr *)e2;
66 return (ra1->reg != ra2->reg);
69 static INLINE int attr_set_hash(region_attr *a) {
70 return HASH_PTR(a->reg);
73 static INLINE region_attr *get_region_attr(void *region) {
74 region_attr r_attr, *res;
77 res = set_find(region_attr_set, &r_attr, sizeof(r_attr), attr_set_hash(&r_attr));
80 r_attr.in_array = NEW_ARR_F(void *, 0);
81 if (is_ir_loop(region))
82 r_attr.op_array = NEW_ARR_F(void *, 0);
84 r_attr.op_array = NULL;
86 r_attr.n_exc_outs = 0;
87 res = set_insert(region_attr_set, &r_attr, sizeof(r_attr), attr_set_hash(&r_attr));
93 int get_region_n_ins(void *region) {
94 return ARR_LEN(get_region_attr(region)->in_array);
97 void *get_region_in(void *region, int pos) {
98 assert(0 <= pos && pos < get_region_n_ins(region));
99 return ((get_region_attr(region)->in_array)[pos]);
102 void add_region_in (void *region, void *in) {
103 ARR_APP1(void *, get_region_attr(region)->in_array, in);
104 get_region_attr(in)->n_outs++;
107 int get_region_n_outs(void *region) {
108 return get_region_attr(region)->n_outs;
111 int get_region_n_exc_outs(void *region) {
112 return get_region_attr(region)->n_exc_outs;
115 void inc_region_n_exc_outs(void *region) {
116 (get_region_attr(region)->n_exc_outs)++;
119 void *get_loop_cfop(void *region, int pos) {
120 assert(0 <= pos && pos < get_region_n_ins(region));
121 return ((get_region_attr(region)->op_array)[pos]);
124 void add_loop_cfop (void *region, void *cfop) {
126 ARR_APP1(void *, get_region_attr(region)->op_array, cfop);
129 static INLINE void exc_outs(void *reg, ir_node *cfop) {
130 if (is_fragile_op(cfop) || (is_fragile_Proj(cfop)))
131 inc_region_n_exc_outs(reg);
134 /*------------------------------------------------------------------*/
135 /* Algorithm to construct the interval edges based on a loop tree. */
136 /* Walk a loop and add all edges. Walk inner loops by recursion. */
137 /*------------------------------------------------------------------*/
139 /* return non-zero if outer can be reached from inner via the outer loop relation */
140 static int find_outer_loop(ir_loop *inner, ir_loop *outer, ir_node *b, ir_node *cfop) {
141 if (get_loop_outer_loop(inner) == outer) {
142 add_region_in(inner, b);
143 add_loop_cfop(inner, cfop);
150 static int test_loop_nest(ir_node *pred_b, ir_loop *nest) {
151 int i, n_elems = get_loop_n_elements(nest);
153 for (i = 0; (i < n_elems); ++i) {
154 loop_element e = get_loop_element(nest, i);
157 if (e.node == pred_b) return 1;
160 if (test_loop_nest(pred_b, e.son)) return 1;
168 static int find_inner_loop(ir_node *b, ir_loop *l, ir_node *pred, ir_node *cfop) {
169 int i, n_elems = get_loop_n_elements(l);
172 for (i = 0; (i < n_elems) && !found; ++i) {
173 loop_element e = get_loop_element(l, i);
176 if (e.node == b) return 0;
179 found = test_loop_nest(pred, e.son);
181 add_region_in(b, e.son);
182 exc_outs(e.son, cfop);
183 //if (is_fragile_op(cfop)) inc_region_n_exc_outs(b);
194 static int find_previous_loop(ir_loop *l, ir_loop *pred_l, ir_node *b, ir_node *pred_b, ir_node *cfop) {
195 ir_loop *outer = get_loop_outer_loop(l);
197 int l_pos = get_loop_element_pos(outer, l);
199 assert(l_pos > 0 && "Is this a necessary condition? There could be a perfect nest ...");
201 for (i = l_pos -1, found = 0; i > -1 && !found; --i) {
202 ir_loop *k = get_loop_element(outer, i).son;
204 found = test_loop_nest(pred_b, k);
207 //if (is_fragile_op(cfop)) inc_region_n_exc_outs(k);
209 add_loop_cfop(l, cfop);
210 add_region_in(b, NULL);
220 * Compute the edges for the interval graph.
222 * @param b The block for which to construct the edges.
223 * @param l The loop of b.
225 * There are four cases:
226 * - The pred block is in the same loop. Add a normal block-block edge.
227 * - The pred block is in a loop contained in this loop, somewhere down in
228 * the nesting. The predecessor of this block is the outermost loop of the nest
229 * directly contained in l.
230 * - The pred block is in the outer loop of l. l gets an edge to the pred block.
231 * - The outer loop of l contains another loop k just before l. The control flow
232 * branches directly from loop k to loop l. Add an edge l->k. Watch it: k must
233 * not be a direct predecessor of l in the loop tree!
235 static void construct_interval_block(ir_node *b, ir_loop *l) {
236 int i, n_cfgpreds = get_Block_n_cfgpreds(b);
238 if (b == get_irg_start_block(current_ir_graph)) return;
239 /* We want nice blocks. */
240 assert(n_cfgpreds > 0);
242 for (i = 0; i < n_cfgpreds; ++i) {
243 ir_node *cfop, *pred;
246 if (is_backedge(b, i)) {
247 if (b != get_loop_element(l, 0).node) {
248 if (get_firm_verbosity()) {
249 ir_printf("Loophead not at loop position 0. %+F\n", b);
252 /* There are no backedges in the interval decomposition. */
253 add_region_in(b, NULL);
257 cfop = get_Block_cfgpred(b, i);
259 if (get_irn_op(get_Proj_pred(cfop)) != op_Cond) {
260 cfop = skip_Proj(cfop);
262 assert(get_nodes_block(cfop) == get_nodes_block(skip_Proj(cfop)));
266 pred = skip_Proj(get_nodes_block(cfop));
267 /* We want nice blocks. */
268 assert( get_irn_op(pred) != op_Bad
269 && get_irn_op(skip_Proj(get_Block_cfgpred(b, i))) != op_Bad);
270 pred_l = get_irn_loop(pred);
272 add_region_in(b, pred);
273 //if (is_fragile_op(cfop)) inc_region_n_exc_outs(b);
274 exc_outs(pred, cfop);
276 int found = find_inner_loop(b, l, pred, cfop);
278 if (b != get_loop_element(l, 0).node) {
279 if (get_firm_verbosity()) {
280 ir_printf("Loop entry not at loop position 0. %+F\n", b);
283 found = find_outer_loop(l, pred_l, pred, cfop);
284 if (found) add_region_in(b, NULL); /* placeholder */
287 found = find_previous_loop(l, pred_l, b, pred, cfop);
290 assert(is_backedge(b, i));
291 assert(found && "backedge from inner loop");
295 if (b != get_loop_element(l, 0).node) {
296 /* Check for improper region */
297 if (has_backedges(b)) {
298 ir_fprintf(stderr, "Improper Region!!!!!! %+F\n", b);
304 static void construct_interval_edges(ir_loop *l) {
305 int i, n_elems = get_loop_n_elements(l);
306 for (i = 0; i < n_elems; ++i) {
307 loop_element e = get_loop_element(l, i);
310 construct_interval_block(e.node, l);
313 construct_interval_edges(e.son);
320 void construct_intervals(ir_graph *irg) {
322 ir_graph *rem = current_ir_graph;
323 current_ir_graph = irg;
325 if (!region_attr_set)
326 region_attr_set = new_set(region_attr_cmp, 256);
328 construct_cf_backedges(current_ir_graph);
330 l = get_irg_loop(current_ir_graph);
332 construct_interval_edges(l);
334 current_ir_graph = rem;
337 void free_intervals(void) {
339 if (!region_attr_set) return;
341 for (ins = (void **)pmap_first(region_in_map);
343 ins = (void **)pmap_next(region_in_map)) {
347 del_set(region_attr_set);
348 region_attr_set = NULL;
351 /*------------------------------------------------------------------*/
352 /* A vcg dumper showing an interval decomposition of a cfg. */
354 /*------------------------------------------------------------------*/
356 void dump_region_edges(FILE *F, void *reg) {
357 int i, n_ins = get_region_n_ins(reg);
359 if (is_ir_node(reg) && get_Block_n_cfgpreds((ir_node *)reg) > get_region_n_ins(reg)) {
360 for (i = n_ins; i < get_Block_n_cfgpreds((ir_node *)reg); ++i) {
361 if (is_backedge((ir_node *)reg, i))
362 fprintf (F, "backedge: { sourcename: \"");
364 fprintf (F, "edge: { sourcename: \"");
365 PRINT_NODEID(((ir_node *)reg));
366 fprintf (F, "\" targetname: \"");
367 PRINT_NODEID(get_nodes_block(skip_Proj(get_Block_cfgpred((ir_node *)reg, i))));
368 fprintf (F, "\" " BLOCK_EDGE_ATTR "}\n");
372 for (i = 0; i < n_ins; ++i) {
373 void *target = get_region_in(reg, i);
375 if (is_ir_node(reg)) {
376 if (get_Block_n_cfgpreds((ir_node *)reg) != get_region_n_ins(reg)) {
377 ir_printf("n_cfgpreds = %d, n_ins = %d\n %+F\n", get_Block_n_cfgpreds((ir_node *)reg), get_region_n_ins(reg), (ir_node*) reg);
381 if ((!target || (is_ir_node(reg) && !is_ir_node(target))) && i < get_Block_n_cfgpreds((ir_node *)reg)) {
382 assert(is_ir_node(reg));
383 if (is_backedge((ir_node *)reg, i))
384 fprintf (F, "backedge: { sourcename: \"");
386 fprintf (F, "edge: { sourcename: \"");
387 PRINT_NODEID(((ir_node *)reg));
388 fprintf (F, "\" targetname: \"");
389 PRINT_NODEID(get_nodes_block(skip_Proj(get_Block_cfgpred((ir_node *)reg, i))));
390 fprintf (F, "\" " BLOCK_EDGE_ATTR "}\n");
392 if (!target) continue;
395 fprintf (F, "edge: { sourcename: \"");
396 if (is_ir_node(reg)) {
397 PRINT_NODEID(((ir_node *)reg));
399 PRINT_LOOPID(((ir_loop *)reg));
401 fprintf (F, "\" targetname: \"");
402 if (is_ir_node(target)) {
403 PRINT_NODEID(((ir_node *)target));
405 PRINT_LOOPID(((ir_loop *)target));
408 if (is_ir_node(reg) && is_fragile_op(skip_Proj(get_Block_cfgpred(reg, i))))
409 fprintf(F, EXC_CF_EDGE_ATTR);
414 #include "execution_frequency.h"
416 void dump_interval_block(FILE *F, ir_node *block) {
418 /* This is a block. Dump a node for the block. */
419 fprintf (F, "node: {title: \""); PRINT_NODEID(block);
420 fprintf (F, "\" label: \"");
421 if (block == get_irg_start_block(get_irn_irg(block)))
422 fprintf(F, "Start ");
423 if (block == get_irg_end_block(get_irn_irg(block)))
426 fprintf (F, "%s ", get_op_name(get_irn_op(block)));
428 fprintf(F, " freq: %9.4lf", get_region_exec_freq(block));
429 fprintf(F, " n_outs: %d", get_region_n_outs(block));
430 fprintf(F, " n_exc_outs: %d", get_region_n_exc_outs(block));
432 fprintf(F, "info1:\"");
433 if (dump_dominator_information_flag)
434 fprintf(F, "dom depth %d\n", get_Block_dom_depth(block));
436 /* show arity and possible Bad predecessors of the block */
437 fprintf(F, "arity: %d\n", get_Block_n_cfgpreds(block));
438 for (fl = i = 0; i < get_Block_n_cfgpreds(block); ++i) {
439 ir_node *pred = get_Block_cfgpred(block, i);
442 fprintf(F, "Bad pred at pos: ");
443 fprintf(F, "%d ", i);
450 fprintf (F, "\""); /* closing quote of info */
452 if ((block == get_irg_start_block(get_irn_irg(block))) ||
453 (block == get_irg_end_block(get_irn_irg(block))) )
454 fprintf(F, " color:blue ");
456 fprintf(F, " color:yellow ");
461 void dump_interval_loop(FILE *F, ir_loop *l) {
462 int i, n_elems = get_loop_n_elements(l);
464 fprintf(F, "graph: { title: \"");
466 fprintf(F, "\" label: \"loop %d", get_loop_loop_nr(l));
467 fprintf(F, " freq: %9.4lf", get_region_exec_freq(l));
468 fprintf(F, " n_outs: %d", get_region_n_outs(l));
469 fprintf(F, " n_exc_outs: %d", get_region_n_exc_outs(l));
470 fprintf(F, "\" status:clustered color:white \n");
472 for (i = 0; i < n_elems; ++i) {
473 loop_element e = get_loop_element(l, i);
474 dump_region_edges(F, e.node);
477 dump_interval_block(F, e.node);
480 dump_interval_loop(F, e.son);
490 void dump_interval_graph(ir_graph *irg, const char *suffix) {
493 if (!is_filtered_dump_name(get_entity_ident(get_irg_entity(irg))))
496 f = vcg_open(irg, suffix, "-intervals");
497 dump_vcg_header(f, get_irg_dump_name(irg), NULL);
499 current_ir_graph = irg;
501 dump_interval_loop(f, get_irg_loop(current_ir_graph));